I survived the explosion of a hydrogen bomb. Hydrogen (thermonuclear) bomb: testing weapons of mass destruction

The geopolitical ambitions of major powers always lead to an arms race. The development of new military technologies gave one country or another an advantage over others. Thus, with leaps and bounds, humanity approached the emergence of terrible weapons - nuclear bomb. From what date did the report of the atomic era begin, how many countries on our planet have nuclear potential and what is the fundamental difference? hydrogen bomb from nuclear? You can find the answer to these and other questions by reading this article.

What is the difference between a hydrogen bomb and a nuclear bomb?

Any nuclear weapon based on intranuclear reaction, the power of which is capable of almost instantly destroying a large number of living units, as well as equipment, and all kinds of buildings and structures. Let's consider the classification of nuclear warheads in service with some countries:

• Nuclear (atomic) bomb. During the nuclear reaction and fission of plutonium and uranium, energy is released on a colossal scale. Typically, one warhead contains two plutonium charges of the same mass, which explode away from each other.
• Hydrogen (thermonuclear) bomb. Energy is released based on the fusion of hydrogen nuclei (hence the name). The intensity of the shock wave and the amount of energy released exceeds atomic energy by several times.

What is more powerful: a nuclear or a hydrogen bomb?

While scientists were puzzling over how to use the atomic energy obtained in the process of thermonuclear fusion of hydrogen for peaceful purposes, the military had already conducted more than a dozen tests. It turned out that charge in a few megatons of a hydrogen bomb are thousands of times more powerful than an atomic bomb. It’s even difficult to imagine what would have happened to Hiroshima (and indeed to Japan itself) if there had been hydrogen in the 20-kiloton bomb thrown at it.

Consider the powerful destructive force that results from a 50 megaton hydrogen bomb explosion:

• Fire ball: diameter 4.5 -5 kilometers in diameter.
• Sound wave: The explosion can be heard from 800 kilometers away.
• Energy: from the released energy, a person can get burns to the skin, being up to 100 kilometers from the epicenter of the explosion.
• nuclear mushroom: height is more than 70 km in height, the radius of the cap is about 50 km.

Atomic bombs of such power have never been detonated before. There are indicators of the bomb dropped on Hiroshima in 1945, but its size was significantly inferior to the hydrogen discharge described above:

• Fire ball: diameter about 300 meters.
• nuclear mushroom: height 12 km, cap radius - about 5 km.
• Energy: the temperature at the center of the explosion reached 3000C°.

Now in the arsenal of nuclear powers are namely hydrogen bombs. In addition to the fact that they are ahead in their characteristics of their " little brothers", they are much cheaper to produce.

The principle of operation of a hydrogen bomb

Let's look at it step by step, stages of detonating hydrogen bombs:

1. Charge detonation. The charge is in a special shell. After detonation, neutrons are released and a heat, required to initiate nuclear fusion in the main charge.
2. Lithium fission. Under the influence of neutrons, lithium splits into helium and tritium.
3. Thermonuclear fusion. Tritium and helium trigger a thermonuclear reaction, as a result of which hydrogen enters the process, and the temperature inside the charge instantly increases. A thermonuclear explosion occurs.

The principle of operation of an atomic bomb

1. Charge detonation. The bomb shell contains several isotopes (uranium, plutonium, etc.), which decay under the detonation field and capture neutrons.
2. Avalanche process. The destruction of one atom initiates the decay of several more atoms. There is a chain process that leads to destruction large quantity cores.
3. Nuclear reaction. In a very short time, all parts of the bomb form one whole, and the mass of the charge begins to exceed the critical mass. Freed up great amount energy, after which an explosion occurs.

The danger of nuclear war

Even in the middle of the last century, the danger of nuclear war was unlikely. Two countries had atomic weapons in their arsenal - the USSR and the USA. The leaders of the two superpowers were well aware of the danger of using weapons of mass destruction, and the arms race was most likely conducted as a “competitive” confrontation.

Of course, there were tense moments in relation to the powers, but common sense always prevailed over ambitions.

The situation changed at the end of the 20th century. The “nuclear baton” was taken possession of not only the developed countries Western Europe, but also representatives of Asia.

But, as you probably know, " nuclear club"consists of 10 countries. It is unofficially believed that Israel, and possibly Iran, have nuclear warheads. Although the latter, after the imposition of economic sanctions on them, abandoned the development of the nuclear program.

After the appearance of the first atomic bomb, scientists in the USSR and the USA began to think about weapons that would not cause such great destruction and contamination of enemy territories, but would have a targeted effect on the human body. The idea arose about creation of a neutron bomb.

The operating principle is interaction of neutron flux with living flesh and military equipment. The more radioactive isotopes produced instantly destroy a person, and tanks, transporters and other weapons become sources of strong radiation for a short time.

A neutron bomb explodes at a distance of 200 meters to ground level, and is especially effective during an enemy tank attack. The armor of military equipment, 250 mm thick, is capable of reducing the effects of a nuclear bomb several times, but is powerless against the gamma radiation of a neutron bomb. Let's consider the effects of a neutron projectile with a power of up to 1 kiloton on a tank crew:

As you understand, the difference between a hydrogen bomb and an atomic bomb is enormous. The difference in the nuclear fission reaction between these charges makes a hydrogen bomb is hundreds of times more destructive than an atomic bomb.

When using a 1 megaton thermonuclear bomb, everything within a radius of 10 kilometers will be destroyed. Not only buildings and equipment will suffer, but also all living things.

The heads of nuclear countries should remember this, and use the “nuclear” threat solely as a deterrent tool, and not as an offensive weapon.

Video about the differences between the atomic and hydrogen bombs

This video will describe in detail and step by step the principle of operation of an atomic bomb, as well as the main differences from the hydrogen one:

On August 12, 1953, the first Soviet hydrogen bomb was tested at the Semipalatinsk test site.

And on January 16, 1963, in the midst of cold war, Nikita Khrushchev announced to the world that the Soviet Union possesses new weapons of mass destruction in its arsenal. A year and a half earlier, the most powerful hydrogen bomb explosion in the world was carried out in the USSR - a charge with a capacity of over 50 megatons was detonated on Novaya Zemlya. In many ways, it was this statement by the Soviet leader that made the world realize the threat of further escalation of the nuclear arms race: already on August 5, 1963, an agreement was signed in Moscow banning nuclear weapons tests in the atmosphere, outer space and under water.

History of creation

The theoretical possibility of obtaining energy by thermonuclear fusion was known even before World War II, but it was the war and the subsequent arms race that raised the question of creating technical device to practically create this reaction. It is known that in Germany in 1944, work was carried out to initiate thermonuclear fusion by compression nuclear fuel using conventional charges explosive- but they were unsuccessful, since it was not possible to obtain the required temperatures and pressure. The USA and the USSR have been developing thermonuclear weapons since the 40s, almost simultaneously testing the first thermonuclear devices in the early 50s. In 1952, on the Eniwetak Atoll, the United States exploded a charge with a capacity of 10.4 megatons (which is 450 times more power bomb dropped on Nagasaki), and in 1953 the USSR tested a device with a yield of 400 kilotons.

The designs of the first thermonuclear devices were poorly suited for actual combat use. For example, the device tested by the United States in 1952 was a ground-based structure the height of a 2-story building and weighing over 80 tons. Liquid thermonuclear fuel was stored in it using a huge refrigeration unit. Therefore, in the future, serial production of thermonuclear weapons was carried out using solid fuel— lithium-6 deuteride. In 1954, the United States tested a device based on it on the Bikini Atoll, and in 1955, a new Soviet one was tested at the Semipalatinsk test site. thermonuclear bomb. In 1957, tests of a hydrogen bomb were carried out in Great Britain. In October 1961, a thermonuclear bomb with a capacity of 58 megatons was detonated in the USSR on Novaya Zemlya - the most powerful bomb ever tested by mankind, which went down in history under the name “Tsar Bomba”.

Further development was aimed at reducing the size of the design of hydrogen bombs to ensure their delivery to the target by ballistic missiles. Already in the 60s, the mass of devices was reduced to several hundred kilograms, and by the 70s ballistic missiles could carry over 10 warheads at the same time - these are missiles with multiple warheads, each of the parts can hit its own target. Today, the USA, Russia and Great Britain have thermonuclear arsenals; tests of thermonuclear charges were also carried out in China (in 1967) and in France (in 1968).

The principle of operation of a hydrogen bomb

The action of a hydrogen bomb is based on the use of energy released during the thermonuclear fusion reaction of light nuclei. It is this reaction that takes place in the depths of stars, where, under the influence of ultra-high temperatures and enormous pressure, hydrogen nuclei collide and merge into heavier helium nuclei. During the reaction, part of the mass of hydrogen nuclei is converted into a large amount of energy - thanks to this, stars constantly release huge amounts of energy. Scientists copied this reaction using hydrogen isotopes deuterium and tritium, giving it the name “hydrogen bomb.” Initially, liquid isotopes of hydrogen were used to produce charges, and later lithium-6 deuteride, a solid compound of deuterium and an isotope of lithium, was used.

Lithium-6 deuteride is the main component of the hydrogen bomb, thermonuclear fuel. It already stores deuterium, and the lithium isotope serves as the raw material for the formation of tritium. To start a thermonuclear fusion reaction, it is necessary to create high temperatures and pressures, as well as to separate tritium from lithium-6. These conditions are provided as follows.

The shell of the container for thermonuclear fuel is made of uranium-238 and plastic, and a conventional nuclear charge with a power of several kilotons is placed next to the container - it is called a trigger, or initiator charge of a hydrogen bomb. During the explosion of the plutonium initiator charge under the influence of powerful X-ray radiation, the container shell turns into plasma, compressing thousands of times, which creates the necessary high pressure and enormous temperature. At the same time, neutrons emitted by plutonium interact with lithium-6, forming tritium. Deuterium and tritium nuclei interact under the influence of ultra-high temperature and pressure, which leads to a thermonuclear explosion.

If you make several layers of uranium-238 and lithium-6 deuteride, then each of them will add its own power to the explosion of a bomb - that is, such a “puff” allows you to increase the power of the explosion almost unlimitedly. Thanks to this, a hydrogen bomb can be made of almost any power, and it will be much cheaper than a conventional nuclear bomb of the same power.

The content of the article

H-BOMB, a weapon of great destructive power (on the order of megatons in TNT equivalent), the operating principle of which is based on the reaction of thermonuclear fusion of light nuclei. The source of explosion energy is processes similar to those occurring on the Sun and other stars.

Thermonuclear reactions.

The interior of the Sun contains a gigantic amount of hydrogen, which is in a state of ultra-high compression at a temperature of approx. 15,000,000 K. At such high temperatures and plasma densities, hydrogen nuclei experience constant collisions with each other, some of which result in their fusion and ultimately the formation of heavier helium nuclei. Such reactions, called thermonuclear fusion, are accompanied by the release of enormous amounts of energy. According to the laws of physics, the energy release during thermonuclear fusion is due to the fact that during the formation of a heavier nucleus, part of the mass of the light nuclei included in its composition is converted into a colossal amount of energy. That is why the Sun, having a gigantic mass, loses approx. every day in the process of thermonuclear fusion. 100 billion tons of matter and releases energy, thanks to which life on Earth became possible.

Isotopes of hydrogen.

The hydrogen atom is the simplest of all existing atoms. It consists of one proton, which is its nucleus, around which a single electron rotates. Careful studies of water (H 2 O) have shown that it contains negligible amounts of “heavy” water containing the “heavy isotope” of hydrogen - deuterium (2 H). The deuterium nucleus consists of a proton and a neutron - a neutral particle with a mass close to a proton.

There is a third isotope of hydrogen, tritium, whose nucleus contains one proton and two neutrons. Tritium is unstable and undergoes spontaneous radioactive decay, turning into an isotope of helium. Traces of tritium have been found in the Earth's atmosphere, where it is formed as a result of the interaction of cosmic rays with gas molecules that make up the air. Tritium is produced artificially in a nuclear reactor by irradiating the lithium-6 isotope with a stream of neutrons.

Development of the hydrogen bomb.

Preliminary theoretical analysis showed that thermonuclear fusion is most easily accomplished in a mixture of deuterium and tritium. Taking this as a basis, US scientists at the beginning of 1950 began implementing a project to create a hydrogen bomb (HB). The first tests of a model nuclear device were carried out at the Enewetak test site in the spring of 1951; thermonuclear fusion was only partial. Significant success was achieved on November 1, 1951 during the testing of a massive nuclear device, the explosion power of which was 4 × 8 Mt in TNT equivalent.

The first hydrogen aerial bomb was detonated in the USSR on August 12, 1953, and on March 1, 1954, the Americans detonated a more powerful (approximately 15 Mt) aerial bomb on Bikini Atoll. Since then, both powers have carried out explosions of advanced megaton weapons.

The explosion at Bikini Atoll was accompanied by the release of large amounts of radioactive substances. Some of them fell hundreds of kilometers from the explosion site on the Japanese fishing vessel "Lucky Dragon", while others covered the island of Rongelap. Since thermonuclear fusion produces stable helium, the radioactivity from the explosion of a pure hydrogen bomb should be no more than that of an atomic detonator of a thermonuclear reaction. However, in the case under consideration, the predicted and actual radioactive fallout differed significantly in quantity and composition.

The mechanism of action of a hydrogen bomb.

The sequence of processes occurring during the explosion of a hydrogen bomb can be represented as follows. First, the thermonuclear reaction initiator charge (a small atomic bomb) located inside the HB shell explodes, resulting in a neutron flash and creating the high temperature necessary to initiate thermonuclear fusion. Neutrons bombard an insert made of lithium deuteride, a compound of deuterium and lithium (a lithium isotope with mass number 6 is used). Lithium-6 is split into helium and tritium under the influence of neutrons. Thus, the atomic fuse creates the materials necessary for synthesis directly in the actual bomb itself.

Then a thermonuclear reaction begins in a mixture of deuterium and tritium, the temperature inside the bomb rapidly increases, involving more and more large quantity hydrogen. With a further increase in temperature, a reaction between deuterium nuclei, characteristic of a pure hydrogen bomb, could begin. All reactions, of course, occur so quickly that they are perceived as instantaneous.

Fission, fusion, fission (superbomb).

In fact, in a bomb, the sequence of processes described above ends at the stage of the reaction of deuterium with tritium. Further, the bomb designers chose not to use nuclear fusion, but nuclear fission. The fusion of deuterium and tritium nuclei produces helium and fast neutrons, the energy of which is high enough to cause nuclear fission of uranium-238 (the main isotope of uranium, much cheaper than the uranium-235 used in conventional atomic bombs). Fast neutrons split the atoms of the uranium shell of the superbomb. The fission of one ton of uranium creates energy equivalent to 18 Mt. Energy goes not only to explosion and heat generation. Each uranium nucleus splits into two highly radioactive “fragments.” The fission products include 36 different chemical elements and almost 200 radioactive isotopes. All this constitutes the radioactive fallout that accompanies superbomb explosions.

Thanks to the unique design and the described mechanism of action, weapons of this type can be made as powerful as desired. It is much cheaper than atomic bombs of the same power.

Consequences of the explosion.

Shock wave and thermal effect.

The direct (primary) impact of a superbomb explosion is threefold. The most obvious direct impact is a shock wave of enormous intensity. The strength of its impact, depending on the power of the bomb, the height of the explosion above the surface of the earth and the nature of the terrain, decreases with distance from the epicenter of the explosion. The thermal impact of an explosion is determined by the same factors, but also depends on the transparency of the air - fog sharply reduces the distance at which a thermal flash can cause serious burns.

According to calculations, during an explosion in the atmosphere of a 20-megaton bomb, people will remain alive in 50% of cases if they 1) take refuge in an underground reinforced concrete shelter at a distance of approximately 8 km from the epicenter of the explosion (E), 2) are in ordinary urban buildings at a distance of approx. . 15 km from EV, 3) found themselves in an open place at a distance of approx. 20 km from EV. In conditions of poor visibility and at a distance of at least 25 km, if the atmosphere is clear, for people in open areas, the likelihood of survival increases rapidly with distance from the epicenter; at a distance of 32 km its calculated value is more than 90%. The area over which the penetrating radiation generated during an explosion causes death is relatively small, even in the case of a high-power superbomb.

Fire ball.

Depending on the composition and mass of flammable material involved in the fireball, giant self-sustaining firestorms can form and rage for many hours. However, the most dangerous (albeit secondary) consequence of the explosion is radioactive contamination of the environment.

Fallout.

How they are formed.

When a bomb explodes, the resulting fireball is filled with a huge amount of radioactive particles. Typically, these particles are so small that once they reach the upper atmosphere, they can remain there for a long time. But if a fireball comes into contact with the surface of the Earth, it turns everything on it into hot dust and ash and draws them into a fiery tornado. In a whirlwind of flame, they mix and bind with radioactive particles. Radioactive dust, except the largest, does not settle immediately. Finer dust is carried away by the resulting cloud and gradually falls out as it moves with the wind. Directly at the site of the explosion, radioactive fallout can be extremely intense - mainly large dust settling on the ground. Hundreds of kilometers from the explosion site and at greater distances, small but still visible to the eye ash particles. They often form a cover similar to fallen snow, deadly to anyone who happens to be nearby. Even smaller and invisible particles, before they settle on the ground, can wander in the atmosphere for months and even years, going around many times Earth. By the time they fall out, their radioactivity is significantly weakened. The most dangerous radiation remains strontium-90 with a half-life of 28 years. Its loss is clearly observed throughout the world. Settling on leaves and grass, it ends up in food chains, including humans. As a consequence of this, noticeable, although not yet dangerous, amounts of strontium-90 have been found in the bones of residents of most countries. The accumulation of strontium-90 in human bones is very dangerous in the long term, as it leads to the formation of malignant bone tumors.

Long-term contamination of the area with radioactive fallout.

In the event of hostilities, the use of a hydrogen bomb will lead to immediate radioactive contamination of an area within a radius of approx. 100 km from the epicenter of the explosion. If a superbomb explodes, an area of ​​tens of thousands of square kilometers will be contaminated. Such a huge area of ​​destruction with a single bomb makes it a completely new type of weapon. Even if the superbomb does not hit the target, i.e. will not hit the object with shock-thermal effects, the penetrating radiation and radioactive fallout accompanying the explosion will make the surrounding space uninhabitable. Such precipitation can continue for many days, weeks and even months. Depending on their quantity, the intensity of radiation can reach deadly levels. A relatively small number of superbombs are enough to completely cover large country a layer of radioactive dust that is deadly to all living things. Thus, the creation of the superbomb marked the beginning of an era when it became possible to make entire continents uninhabitable. Even after long time after termination direct impact radioactive fallout will remain dangerous due to the high radiotoxicity of isotopes such as strontium-90. With food grown on soils contaminated with this isotope, radioactivity will enter the human body.

There are a considerable number of different political clubs in the world. The G7, now the G20, BRICS, SCO, NATO, the European Union, to some extent. However, none of these clubs can boast of a unique function - the ability to destroy the world as we know it. The “nuclear club” has similar capabilities.

Today there are 9 countries that have nuclear weapons:

• Russia;
• Great Britain;
• France;
• India
• Pakistan;
• Israel;
• DPRK.

Countries are ranked as they acquire nuclear weapons in their arsenal. If the list were arranged by the number of warheads, then Russia would be in first place with its 8,000 units, 1,600 of which can be launched even now. The states are only 700 units behind, but they have 320 more charges at hand. “Nuclear club” is a purely relative concept; in fact, there is no club. There are a number of agreements between countries on non-proliferation and reduction of nuclear weapons stockpiles.

The first tests of the atomic bomb, as we know, were carried out by the United States back in 1945. This weapon was tested in the “field” conditions of World War II on residents of the Japanese cities of Hiroshima and Nagasaki. They operate on the principle of division. During the explosion, a chain reaction is triggered, which provokes the fission of nuclei into two, with the accompanying release of energy. Uranium and plutonium are mainly used for this reaction. Our ideas about what they are made of are associated with these elements. nuclear bombs. Since uranium occurs in nature only as a mixture of three isotopes, of which only one is capable of supporting such a reaction, it is necessary to enrich uranium. The alternative is plutonium-239, which does not occur naturally and must be produced from uranium.

If a fission reaction occurs in a uranium bomb, then a fusion reaction occurs in a hydrogen bomb - this is the essence of how a hydrogen bomb differs from an atomic one. We all know that the sun gives us light, warmth, and one might say life. The same processes that occur in the sun can easily destroy cities and countries. The explosion of a hydrogen bomb is generated by the synthesis of light nuclei, the so-called thermonuclear fusion. This “miracle” is possible thanks to hydrogen isotopes - deuterium and tritium. This is actually why the bomb is called a hydrogen bomb. You can also see the name “thermonuclear bomb”, from the reaction that underlies this weapon.

After the world saw the destructive power of nuclear weapons, in August 1945, the USSR began a race that lasted until its collapse. The United States was the first to create, test and use nuclear weapons, the first to detonate a hydrogen bomb, but the USSR can be credited with the first production of a compact hydrogen bomb, which can be delivered to the enemy on a regular Tu-16. The first US bomb was the size of a three-story house; a hydrogen bomb of that size would be of little use. The Soviets received such weapons as early as 1952, while the United States' first "adequate" bomb was adopted only in 1954. If you look back and analyze the explosions in Nagasaki and Hiroshima, you can come to the conclusion that they were not that powerful . Two bombs in total destroyed both cities and killed, according to various sources, up to 220,000 people. Carpet bombing of Tokyo could kill 150-200,000 people a day even without any nuclear weapons. It's connected with low power the first bombs were only a few tens of kilotons of TNT. Hydrogen bombs were tested with an aim to overcome 1 megaton or more.

First Soviet bomb was tested with an application for 3 Mt, but in the end they tested 1.6 Mt.

The most powerful hydrogen bomb was tested by the Soviets in 1961. Its capacity reached 58-75 Mt, with the declared 51 Mt. “Tsar” plunged the world into a slight shock, in the literal sense. The shock wave circled the planet three times. There was not a single hill left at the test site (Novaya Zemlya), the explosion was heard at a distance of 800 km. The fireball reached a diameter of almost 5 km, the “mushroom” grew by 67 km, and the diameter of its cap was almost 100 km. The consequences of such an explosion in big city hard to imagine. According to many experts, it was the test of a hydrogen bomb of such power (the States at that time had bombs four times less powerful) that became the first step towards signing various treaties banning nuclear weapons, their testing and reducing production. For the first time, the world began to think about its own security, which was truly at risk.

As mentioned earlier, the principle of operation of a hydrogen bomb is based on a fusion reaction. Thermonuclear fusion is the process of fusion of two nuclei into one, with the formation of a third element, the release of a fourth and energy. The forces that repel nuclei are enormous, so in order for the atoms to come close enough to merge, the temperature must be simply enormous. Scientists have been puzzling over cold thermonuclear fusion for centuries, trying, so to speak, to reset the fusion temperature to room temperature, ideally. In this case, humanity will have access to the energy of the future. As for the current thermonuclear reaction, to start it you still need to light a miniature sun here on Earth - bombs usually use a uranium or plutonium charge to start the fusion.

In addition to the consequences described above from the use of a bomb of tens of megatons, a hydrogen bomb, like any nuclear weapon, has a number of consequences from its use. Some people tend to believe that the hydrogen bomb is a “cleaner weapon” than a conventional bomb. Perhaps this has something to do with the name. People hear the word “water” and think that it has something to do with water and hydrogen, and therefore the consequences are not so dire. In fact, this is certainly not the case, because the action of the hydrogen bomb is based on extremely radioactive substances. It is theoretically possible to make a bomb without a uranium charge, but this is impractical due to the complexity of the process, so the pure fusion reaction is “diluted” with uranium to increase power. At the same time, the amount of radioactive fallout increases to 1000%. Everything that falls into the fireball will be destroyed, the area within the affected radius will become uninhabitable for people for decades. Radioactive fallout can harm the health of people hundreds and thousands of kilometers away. Specific numbers and the area of ​​infection can be calculated by knowing the strength of the charge.

However, the destruction of cities is not the worst thing that can happen “thanks” to weapons of mass destruction. After a nuclear war, the world will not be completely destroyed. Thousands of large cities, billions of people will remain on the planet, and only a small percentage of territories will lose their “livable” status. In the long term, the entire world will be at risk due to the so-called “nuclear winter.” Detonation of the “club’s” nuclear arsenal could trigger the release of enough substance (dust, soot, smoke) into the atmosphere to “reduce” the brightness of the sun. The shroud, which could spread across the entire planet, would destroy crops for several years to come, causing famine and inevitable population decline. There has already been a “year without summer” in history, after a major volcanic eruption in 1816, so nuclear winter looks more than possible. Again, depending on how the war proceeds, we can get the following types global change climate:

• a cooling of 1 degree will pass unnoticed;
• nuclear autumn - cooling by 2-4 degrees, crop failures and increased formation of hurricanes are possible;
• an analogue of the “year without summer” - when the temperature dropped significantly, by several degrees for a year;
• Little Ice Age – temperatures may drop by 30–40 degrees for a significant period of time and will be accompanied by depopulation of a number of northern zones and crop failures;
• ice age - development of small ice age when reflection sun rays from the surface can reach a certain critical point and the temperature will continue to fall, the only difference is the temperature;
• irreversible cooling is a very sad version of the Ice Age, which, under the influence of many factors, will turn the Earth into a new planet.

The nuclear winter theory has been constantly criticized, and its implications seem a bit overblown. However, there is no need to doubt its inevitable offensive in any global conflict involving the use of hydrogen bombs.

The Cold War is long behind us, and therefore nuclear hysteria can only be seen in old Hollywood films and on the covers of rare magazines and comics. Despite this, we may be on the verge of a, albeit small, but serious nuclear conflict. All this thanks to the rocket lover and hero of the fight against US imperialist ambitions - Kim Jong-un. The DPRK hydrogen bomb is still a hypothetical object; only indirect evidence speaks of its existence. Of course the government North Korea constantly reports that they managed to make new bombs, but so far no one has seen them live. Naturally, the States and their allies - Japan and South Korea, are a little more concerned about the presence, even hypothetical, of such weapons in the DPRK. The reality is that this moment The DPRK does not have enough technology to successfully attack the United States, which they announce to the whole world every year. Even an attack on neighboring Japan or the South may not be very successful, if at all, but every year the danger of a new conflict on the Korean Peninsula is growing.

Everyone has already discussed one of the most unpleasant news of December - North Korea's successful testing of a hydrogen bomb. Kim Jong-un did not fail to hint (directly state) that he was ready at any moment to transform weapons from defensive to offensive, which caused an unprecedented stir in the press around the world. However, there were also optimists who declared that the tests were falsified: they say that the shadow of the Juche is falling in the wrong direction, and somehow the radioactive fallout is not visible. But why is the presence of a hydrogen bomb in the aggressor country such a significant factor for free countries, since even nuclear warheads, which North Korea has in abundance, have never scared anyone so much?

The hydrogen bomb, also known as the Hydrogen Bomb or HB, is a weapon of incredible destructive power, whose power is measured in megatons of TNT. The principle of operation of HB is based on the energy that is generated during thermonuclear fusion of hydrogen nuclei - exactly the same process occurs in the Sun.

How is a hydrogen bomb different from an atomic bomb?

Nuclear fusion, the process that occurs during the detonation of a hydrogen bomb, is the most powerful type of energy available to humanity. We have not yet learned how to use it for peaceful purposes, but we have adapted it for military purposes. This thermonuclear reaction, similar to what can be seen in stars, releases an incredible flow of energy. In atomic energy, energy is obtained from the fission of the atomic nucleus, so the explosion of an atomic bomb is much weaker.

First test

And the Soviet Union was once again ahead of many participants in the Cold War race. The first hydrogen bomb, manufactured under the leadership of the brilliant Sakharov, was tested at the secret Semipalatinsk test site - and, to put it mildly, they impressed not only scientists, but also Western spies.

Shock wave

The direct destructive effect of a hydrogen bomb is a powerful, highly intense shock wave. Its power depends on the size of the bomb itself and the height at which the charge detonated.

Thermal effect

A hydrogen bomb of only 20 megatons (the size of the largest bomb tested so far is 58 megatons) creates a huge amount of thermal energy: concrete melted within a radius of five kilometers from the test site of the projectile. Within a nine-kilometer radius, all living things will be destroyed; neither equipment nor buildings will survive. The diameter of the crater formed by the explosion will exceed two kilometers, and its depth will fluctuate about fifty meters.

Fire ball

The most spectacular thing after the explosion will seem to observers to be a huge fireball: flaming storms initiated by the detonation of a hydrogen bomb will support themselves, drawing more and more flammable material into the funnel.

Radiation contamination

But most dangerous consequence explosion will, of course, cause radiation contamination. The disintegration of heavy elements in a raging fiery whirlwind will fill the atmosphere with tiny particles of radioactive dust - it is so light that when it enters the atmosphere, it can circle the globe two or three times and only then fall out in the form of precipitation. Thus, one explosion of a 100 megaton bomb could have consequences for the entire planet.

Tsar bomb

58 megatons - that's how much the largest hydrogen bomb, exploded at the test site of the Novaya Zemlya archipelago, weighed. The shock wave circled the globe three times, forcing the opponents of the USSR to once again become convinced of the enormous destructive power of this weapon. Veselchak Khrushchev joked at the plenum that they didn’t make another bomb only for fear of breaking the glass in the Kremlin.